Universal joint



Aug. 31, 1943. A. F. GREINER UNIVERSAL JOINT Filed Feb. 5, 1941 3 Sheets-Sheet l INVENTOR.

ANTON E GREINER Aug. 31, 1943. v A. F. GREINER' UNIVERSAL JOINT Filed Feb. 3, 1941 3 Sheets-Sheet 2 FlG.6;

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mvzzvron. FG ANTON E GREINER Y AIQQQHMM+ ATTORNEYS Aug. 31, 1943.

A. F. GREINER UNIVERSAL JOINT 3 Sheets-Sheet 3 Filed Feb. 3, 1941 A INVENTOR. AN'TQN E GREINER ATTQRNEYS es fa FIG.|6.

Patented Aug. 31, 1943 ApplicationFebruary s, 1941, Serial No. 377,259

a Claims.

This invention relates generally to torque transmitting mechanism and refers more par-' ticularly toimprovements in torque transmitting universal joints.

One type of universal joint which has achieved considerable recognition in the trade fortransmitting torque between relatively angjularly, movable driving and driven members comprises a yoke having two pairs of journals. The journals of one pair extend radially outwardly from diametrically opposite sidesof the yoke and are respectively connectedto the driving member through the medium of bearings. The other pair of journals extends radially outwardlyfrom diametrically oppositesides of the yoke between the journals of thetfirst pair and are respectively connected to the driven member through the medium of bearings carried by the latter. The bearings usually include needle roller bearings located between the journals and adjacent surfaces of thebearings. V y l V In universal joints of the above type, both the bearings and the journals are rigidly fixed with respect to each other. As a result, the

angleof deflection of the journals has a positive value under torque load and the angle of :deflection of thebearings is, of course,'zero under all torque conditions. This ditlerence between the angle of deflection of the journals and the angle of deflection of the bearings under torque load subjects the, needle bearings to adverse force moments which tends to change the normalline contact of the rollers with the journalsto a point contact. Accordingly,the needle bearing, rollers digfinto the hardened journals and produce indentations in the latter of such depth as to cause failure, of the joint. As a matter of fact, many automobile accidents can be, traced to failure of theuniversal joints and,

therefore, it is important to eliminate the causes of such failures.

It is one of the principal objectsof this invention to overcome the above objections .by providing a torque transmitting device con structed in such a manner that torsional stresses and other adverse force moments are, reduced to a minimum. According to this invention, the

above is accomplished by. providing a bearing and journal capable of relative movement under torque load in directions to permit one to follow the movements and deflections of the other regardless of thenature of thejload conditions.

Another object of this invention is toprovide a torque transmitting universal Joint of the gen eral type set forth above wherein the angle of shown in Figure 12;

rollers with the journals is insuredunder all torque conditions, and the damaging indentations in the journals, previously referred to, are eliminated. 1,

Still another object of this invention is to provide a dual torque transmitting universal joint permitting relative movement of the driving and driven members throughout a wide angle without binding or affecting the efiiciency of the drive through the joint. 3 s r i Another object of the present inventionis to provide a torquetransmitting universal joint embodying a lubricating system which insures uniform lubrication of all parts of the joint and thereby contributes materially in reducing the Wear of the parts to a minimum. i

A further feature of this invention is to provide a torque transmitting device composed of a relatively few simple parts capable of being readily assembled and connected tothe driving and driven members. 1 i

The foregoing as well as other objects will be made more apparent as this description proceeds, especially when considered in connection withthe accompanying drawings, wherein:

Figure l is a side elevational view partly in section of a torque transmitting devicecorrstructed in accordance with this invention;

Figure 2 isa topplan view of the construction shown inFigure 1 .having certain parts broken away forthe sake of clearness; H

Figure '3 is a sectional view taken on the line 33 of Figure 1;

V Figure 4 is a sectional 4-4 of Figure 1;

Figures 5 to 8; inclusive,are diagrams of a torque transmitting device;

Figure 9 is asectional view taken on the line 9+9 of Figure 4; l i i v Figure 10 is a fragmentarysectional view of a slightly modified form of the invention;

Figure 11 is a fragmentary sectional view illustrating a further modification of t the present invention;

view taken on the line Figure 12 is a side elevational view of still another embodiment of this invention;

Figure 13 is a plan view. of the construction Figure 14 is a sectional view takenon the line IL-Moi Figure 12; i

Figure 15 is a sectional View taken on the line iii-i5 of Figure 12, and

Figure 16 is a side elevational View partly in section of a further modification of this invention.

Although a number of the principles of the present invention may be advantageously used in connection with various different types of torque transmitting devices, nevertheless, the invention is particularly applicable when applied to torque transmitting'universal joints and, accordingly, I have selected this embodiment of the invention for the purpose of illustration.

In Figures 1 and 2 of the drawings, I have shown a drive shaft l9 and a driven shaft I! operatively. connected by means of a universal joint l2 constructed to effectively transfer the torque from the driving shaft lil to the driven shaft II regardless of the angular positions of these shafts with respect to each other. In detail it will be noted that the universal joint I? is provided with a yoke li'having two pairs of journals I4 and I5 respectively. The journals Hi extend radially outwardly from diametrically oppositesides of the body portion of the y ke and have. a common ax s perpendicular to the axis of rotation oithe yoke.- The journal l5 extend radially outwardly from diametrically opposite sides of the body portion of the yok between the journ I.4 an have a common xis pe e dicular tothe axis of the journals l4.

lnthepresent in ta c he journa s M. a operatively-oonnected to the driving shaft; it, and the journal 15 are operatively connected to the driven shaft I! so that torque is transmittee, from one shaft to the other throughthe yoke. Upon reference to Figure 1, it will be noted thatthe connection between the driving shaft l0 and the journals M on th yoke i3 in.- cludes a coupling l6 having a tubular hubportion l'l nonrotatably secured to the drive shaft ID by meansof splines l8, or other suitable. fas tening devices. One end of the couplin it extends beyond the adjacent end of the drive shaft ID and is provided with diametrically opposed radially outwardly extending ears E8 on which bearings'ill are supported in a manner to be more fullyhereinafter described. It will suffice to point out at this time that the bearings 26 are in the form of radially inwardly opening caps adapted to respectivelyreceive the journals M.

In accordance. with conventional practice, a plurality of needle bearing rollers'.,2l are supported around the journals l4 and the adjacent inner cylindrical surfaces of the bearing caps. axis of each needle bearing roller is parallel to the common axis of th journal I4 so that the needle bearing rollers normally have a line contact with the cylindrical surfaces of the journals and bearings. In the present instance, the. use

dle bearing rollers 2 I' are held in place by means of washers 22 respectively pressed into-the open ends of the bearings and forming abacking for the packing rings 23 which are. held in place by suit-able shoulders 24 formed on the radially inner ends of the journal l4.

Upon reference to Figure 2, it will be noted that the end of the driven shaft adjacent the yoke 13 is provided with a head 25 having diametrically opposed ears 2-6. similar to the ears l9 previously. described and adapted to support bearings 21 in a manner which will be more fully hereinafter set forth. The bearings 21 are also'in the form of radially inwardly opening caps and respectively receive the journals 15., A

The

pluralityof needle bearing rollers 28 surround each journal I5 in the associated bearing 21 in exactly the same manner previously described, and the needle bearings 23 are held in place by means similar to the means described above for holding the needle bearings 2! in position. The above construction is such that torque is transmitted from one shaft to the other through bearings and journals carried by the yoke l3. It will also be noted thatawith the above construotion, the shafts may assume different angular positions with respect to each other without interfering with the transmission of torque from one shaft to the other.

In order to insure proper lubrication of the several parts of the joint, it will be noted from Figure 4 that the body portion of the yoke 53 is formed with an axially extending bore 39 therethrough having a lining 32 in the form of asheet metal annulus pressed into the bore. As shown in Figure 9, theannlllus 32 is formed with an annular groove intermediate the-ends thereof which cooperates with the adjacent sur face of the bore 38 to form a closedoil groove 3 I. The annular groove 31 is supplied with lubricant through a port 33 formed in the body portion of the yoke and communicating with the annular groove 3!. It will further be observed from Figure i that each journal is formed with a, radially extending passage having the inner end communicating with the annular groove 3! and having the outer end communicating with the interior of the associated bearing -with the result that lubricant, is supplied to the needle bearing. It may be pointed out at this tim that each of the bearings 2i), 2'! are formed with ports 35 therethrough for supplying lubricant to the exterior surfaces of the bearings, andthereason for lubricating these surfaces will be presently set forth.

In order to insure delivery of substantially the same amount of lubricant to each of the needle bearings, the passages 34 and E i through the journals l4, l5 (respectively) at opposite sides of the lubricant supply port. 33 are of smaller cross sectionalarea than the passages 3 5* and 34 through the journals -remote'from the port 33. Also, the quartersection of the oil groove extending between the inner ends of the passages 34 and Sa is ofsmaller cross sectional area than the cross sectional area of the remainder of the groove 3i. The construction is such asto afford agreater resistance to the flow of lubricant to the journals'immediately adjacent the lubricant supply port 33 than'is afforded to the flow of lubricant to the journals remote from the port.33. The relative sizes of the different portions of the'lubricant passages being deter-- mined in dependence upon the consistency of the lubricant used. Asa result, each bearing is insured of its share of the lubricant regardless of the positionof the bearing relative to the lubricant supply port 33.

Figure 5 of the drawings, I have illustrated a diagram of a cross representing the yoke IS. The arms A, B, C, and D on the cross represent the four journals previously referred to as extending radially outwardly from the yoke. lhe line. T in the diagram indicates the driving torque, and the line R indicates the'torque reaction. The dotted lines shown in thediagram represent the'defiection of the arms caused by subjecting the yoke. Hi to torque. In other-words, whenthe yoke I3 is subjected to torque, the points E, F, and'G on the arm A,for example, move to the positions H,I, and J respectively. 'I'hedistance E, G representsthe length of onejournal, and

the point F is thecenter pointof the journal. It follows from the above that-the point Eof the journal moves through a greater distance than the point G when the journal is subjected to a torque load. It will of course, be understood that the same remarks hold true with respect to the other three arms B, C, and D. a

"With the above in mind, reference 'w ill now be made to the diagram shown in Figure6, differing from the illustrationshownin Figure 5 in that the deflectionof the journals on the yoke is constrained by bearings K, L, M, andf-N. In accordance with conventional practice, the bearirigs are, in turn, rigidly held in supports diagrammatically indicated by the reference characters O, P, Q, and R, respectively. jAssuming now that the cross" or yoke I3 is subjected to the driving torque T and torque reaction R, it will be noted that the arms of Journals deflect in the manner indicated by the dotted lines in Figure-6. The difference in deflection ofthe arms shown in Figure 6 and the arms shown inFigure 5 is, ofcourse, due to the fact that the arms,

in Figure 6, arerestrainedby" the rigid supports forthe bearings. In detail, it will be noted that jln Figure 6 the Journal or arm A is compelled to deflect about the center point F which, of course,

does not move. a result, the pointE on the armA moves to the point H in onedirection, and the point G on the armA moves in an Opposite direction to the point J. e I

The above deflection of the arms, or journals tends to cook theneedle bearing rollers surrounding the journals tofsuchwan extent that these rollers have merely a point contact with the adjacentbearing surfaces instead of the desirable line contact which exists under normal circumstances when no torque is being transmitted. In

other words, with the above construction, the deflection S of the bearingshas a positive value as distinguishedfrom the angle of deflection of the rigidly s pported bearings for the journals which has a zero value. The result of the point con-v .7

tact of the needle bearing rollerswith the journals is graphically indioatjed in FigureB of the drawings wherein the oblique indentations .36 on the journals represent the" outlines of the'needle bearing rollers which have been pressed into the hardened surface'of the journals to suchan extent that the latter are notfit for future use. The illustration in Figure 8 is the direct result of the deflection of the journals under torque load when the bearings -for'the Journals are rigidly supported and manyaccidents can be traced to the failure of the joint caused by this condi- A pointed out above, it is one of the principal objects of this invention to support the bearings i 20, 21for the journals in such a manner that these bearings may adjust themselves under torque load relative to their respective supporting means to compensate for deflection "of the journals. In other words,'the bearingsZll, 21 are movably mounted on their respective supports 1 9,

2610, inefifect, follow the deflection of the journals. Before describingpthe manner in which the journals aremounted on theirrespective supports, reference is made to'Figure '7 whichillustrates the action of the yoke under torque loads y when the journals are supported inmovable bear ings. Asdiagrammatically showri' in Figure 7. thebearings 20, 21 are rotatable relative to their fixed supports substantially'about the axes F in dependence upon deflection of the joumals. As aresult, the bearings are; free to adjust themselves under torque loads to the motions and deflections of their respective journalscaused by the transfer of'torque through the journals. It followsy therefore, that deflectionof the needle bearing'rollers relative to the joumals is reduced to arninimum and that the desired line contact of the rollers with theiournals is maintained regardless of i the nature of the load conditions.

*Upon reference to Figures 3 and 4, it will be notedthat each bearing 20, 21 is in the form of an inwardly open cup-shaped member having a substantially flat outer wall 31 and having cylin drical opposed side walls 38 concentric with the axi In addition, each bearing has a stud,

also,"concentric with the axis F and projecting from thefront wall of the bearing. Each of the ears [9, 26 is formed with a recess for'receiving one'ofthe bearings, and the surfacesof the recess adjacentthe cylindrical *surfaces"38 of the bearing are concentric with the latter surfaces. The arrangement is such that the cylindrical surfaces 38 onthe bearings 20, 21 cooperate with the cylindrical surfaces on the ears I 9, 26 (respectively) to support the bearings for rotative movement about the axes F.

v As stated above,- the bearings 20 are secured to the ears l9 on the drive shaft coupling l6, and

the bearings 21 are secured'to the ears 26 on the head 25Qofthedriven shaft II. This is accomplished by extending the studs 38' on the bear.

44 formed in the studs 42. Another alternative is"shown[inFigure 10 wherein the free ends of the studs project beyond theears and are provid'ed with annular grooves 45 for receiving securingrings 46. Regardless of the nature of the fastening means provided for the bearings, the

construction is such as to not only insure the transfer of torque through the bearings but, to

also permit movement of the bearings relative to their respective supports under torque loads. It is pointed out at this time that the cylindrical surfaces of the recesses 39 in the ear is, 26 not only rotatably support the bearings but, also cooperate with th studs 38' to transfer torque from one shaft to the other; It may also be pointed out atthls time that the cooperatingengaging surfaces of therecesses 39 and bearings are lubricated by the escape of lubricant through the ports 35 previously described. In the event it is desired to eliminate the ports;35, thecooperating engaging surfaces may be coated with a relatively soft metal, such as copper zinc or lead so 7 as to provide drylubrication of the surfaces. s

In addition to theforegoing, it will be noted that the'studs' 38 are formed integral with the bearings; As a result, the number of separate partsof the joint'is reduced to aminimum which is advantageousnot only because it reduce the cost of manufacture butjaIsoQbecauSe it simplifies and reduces .the tirne requiredfor assemmy." i a Incases where thetorquereactiontis relatively reat and substantial movement oi the bearings relative to their supports is required tocompensate for torque deflection ofthejournals; it is de-, sirable to secure the bearings on their respective supports in such a manner that the bearings may have a universal movement relative to their supports. With this inmind, reference is made to Figure 11 wherein the'support for one of the bearings is shown in detail, and'it is' to be understood that the supports for the other bearings are identical in construction. lit may be pointed out that the recess 50 in the bearing supporting ear corresponds to the recess 39 shown'in Figure 3 exceptthat the bearing surface of the recess is spherical instead of cylindrical as in the'first described form of the invention. The spherical surface of the recess 50 is concentricwith the axis of the journal extending; into the bearing and the outerysuriace 52 of the bearing is spherically shapedto havea bearing engagement with the spherical surface ;of the recess 59. In other words, the construction is such that'the bearing engages the ear 51' in a manner to provide universal adjustment of the bearing relative to the ear. I

It will also be noted from Figure 11- that the bearing is provided with. a stud 53 which extends thrOugh an opening 54 in theear iii and projects beyond the surface 55 of the ear for threadedly receiving a clamping nut 56. The surface 55 0f the ear is spherical and is concentric withthe spherical surfaceill. Theadjacent side of the nut 56 is also spherical and-is concentric with the spherical surface 55 with the result that the hearing has a limited universal movement relative to the ear 5!. Of course, it will be understood that sufficient clearance is provided between the shank of the stud '53 and the side walls of the opening 54 to permit the desired range of adjustment of the bearing under torque load.

, Referring now to the embodiment of the invention shown in Figures 12 to 15, inclusive, it will be noted that I hav illustrated a dual torque transmitting joint. In these figures, the-reference characters 60 and BI respectively indicate driving and driven shafts having the adjacent ends spaced from each other. A coupling is splined onthe driving shaft 60 and this coupling is. identical in construction to the coupling I 6. deg scribed in connection with the first embodiment of this invention. Accordingly, the same reference characters are used to indicate the corresponding parts of the twocouplings. I

Accouplingtz is splined on the driven shaft and this coupling, is' provided with ahead portion identical in construction to the head portion 25 previously described. Consequently; the same reference characters are used to indicatev corresponding parts of the heads. It may be pointed out, however, that the relationship. between the earszfi on the head 25 and the cars '19, on the coupling i6 differ from the relationship shown "in Figures 1 and 2. Upon reference toFigures 12 and 13, it will be noted that the ears IS on the coupling 16 andthe ears 26 on the head lfi are disposed in substantialcommon plane instead of being arranged-at right angles to each other as in the first described form of the invention. Positioned between the coupling l6 and the head 25 is a pairof yokes which need not be described in detail since they are identical in construction to the yoke l3 previously described. Accordingly, the same reference characters applied to the yoke l3 in the first described form of the invention are used toindicate corresponding parts of the two yokes'shown in Figures 12' to 15, inclusive. It may be pointed out,=fhowever,- that the pair of journals I on one yoke arefconnected to the cars 19 on the coupling [6 by bearings identical in constructionto the bearingszil previously described andthatthe, journals M on the other yoke are connected to the'ears 26 on thehead25 by. bearings corresponding to the bearings 21 previously described. Inasmuch as the bearings are identical in construction to the bearings described in connection with the first embodiment of the invention, I have used the same reference characters to indicate corresponding parts thereof. Q v p Positioned between the yokes is a torque transmitting element 64 having the opposite endsrespectively connected to-the journals l5 on the yokes IS. A pair of'bearings 65 are supported at opposite sides ofone end of the torque-transmitting element li iand respectively receive the journals l5 extending from one side of the yokes 13; A second pair of bearings are supported at opposite. sides of the other end of the torque transmitting element 54 and respectively receive the other journals Won the yokes. In detail, the pair of bearings 65 are integrally connected together by means of a shaft til and the pair-of bearings 66 are integrally connected together by means of a shaft 63. The shafts 6'! and 68 are respectively rockably mounted in opposite ends of the torque transmitting element {E i so as to permit limited rocking movement of the hearings to compensate for deflections of the journals i5 under torque load.

In the interest of simplicity of manufacture andv assembly, the oppositeends of the torque transmitting element 64 are slotted :as at 6%. The. slots open through the opposite ends of the element 64 and respectively receive the shafts 61 and 68. The shaftsare held in assembled relationship withlthe respective slots by means of pins 'H] extending transversely through the opposite ends of the'element 6% beyond the shafts t1. and 68. .It will be noted from Figure 12 that the shaftsfil and 68 are provided with annular grooves 'Hlfor receiving the inner portions of the pins 1i) in. a mannento permit the limited rocking movement of the shafts and associated bearings required to compensate for torque reactions. It may be pointed out at this time that while the mountings for the various bearings shown in Figures 12 to 15, inclusive, are substantially the same as the mountings previously described in connection with the first embodiment of this invention, nevertheless, the bearingmountings shown in Figure ll may be employed in the event'it is desired to compensate for the relatively small torsional movement I of the journals under torque load. This movemerit, however, is usually so small as compared to the deflection of the journals that it may be saiely disregarded.

us, from the foregoing it will ,be noted that I have provided a dual. universaljo-int wherein the construction of the jointat one side of the median plane indicated by the reference chara'cter 12 in Figure 13' is identical to the construction'at the opposite side of this plane and this is advantageous in that it insures efiicient operation of the joint regardless of the relative angu lar. displacement of the driving and driven shafts. -In addition, it will be noted that the dual joint is so constructed as to provide for a wide angle. of deflection of the driving and driven shafts which, of course, is advantageous in bearings 85.

another 1construction, embodying the general a principles described in connection with the above modifications; In detail, the reference character 15 in Figure 16 indicates a tubular driven shaft 'operatively connected to a drive shaft (not shown) through the medium of a universaljoint l6 and a cup-shapedstamping 11. The closed end of the stamping I1 is slightly reduced and is sleeved into the forward end of the driven shaft 15. The reduced portion of the cup-shaped stamping is weldedor otherwise permanently secured to. the driven shaft so as to rotate as a unit therewith.

The universal joint 16 comprises a yoke 18 identical inconstruction to the yoke I3 described in connection withthe first embodiment of this invention. According y, corresponding parts, of

the two yokes are indicated by the same reference characters. The journals l5 onthe yoke are respectively. connected to the stamping l1, and the journals l4 are respectively connected to the driving member which is not, shown in Figure 16. In this connection, it will be noted that the diametrically opposite side walls of the stamping 11 are cut away to form openings 19 of suflicientsize to provide clearance for the journals l4 and their associated bearings.

The openings 19 form diametrically opposed ears 80 at the forward end of the stamping H, and the ears are fashioned with aligned openings 8| therethrough for respectively receiving the journals I5. A circular flange 82 extends radially outwardly from the ears at the marginal edges of the openings 8| and terminate in laterally extending annular flanges 83. A retainer sleeve 84 is pressed into each of the openings 8| and the radially inner end of the sleeve is shaped to retain a spherically contoured bearing 85. The radially outer end of each retainer sleeve 84 is provided with a laterally outwardly extending annular flange 86 adapted to be clamped against the annular flange 83 by means of a cap 81 having the peripheral edge crimped over the radially inner sides of the annular flanges 83. The central portion of the cap is spherically shaped to engage the bearing 85 and cooperates with the retainer to provide for limited universal adjustment of the bearing.

The bearings 85 are provided with cylindrical bores opening through the radially inner sides of the bearings and adapted to respectively re-,

ceive the journals IS on the yoke l3. In the present instance, needle bearing rollers 90 are supported between the cylindrical surfaces of the journals [5 and the adjacent surfaces of the These needle bearing rollers are retained in assembledrelation with the bearings and are lubricated in the same manner defined in connection with the first embodiment of this invention. In this connection, it will be noted that each of the bearings has a port 9| through the radially outer side thereof for supplying lubricant to the spherically shaped surfaces of the caps 81. I

The journals M of the yoke l3 shown in Figure 16 may be connected to the driving member (not shown) in the same manner as the journals l5.

However, I have shown the journals M as adapted to be connected to the driving member. (not shown) by bearings which are similar to the torque load conditions and as a result the angle of deflection of the bearings is at alltimes and under any load conditions substantially equal to the angle of deflection of the .journals. Consequently, the objectionable point contact of the needle bearings with the journalsis avoidedand efficient operation of the universal joint over long. period of time is insured; i

What I claim as my invention is:

1. In a torque transmitting universal joint, driving and driven members having the adjacent ends spaced from eachother, a pair of yokes positioned between the adjacent ends of the members, a pairof journals extending radially outwardly from diametrically opposite sides of each yoke and having a common axis, a pair of bearingsrespectively connecting the journals on one yoke to the adjacent end of one of said members, asecond pair of bearingsrespectively connecting the journals on the second yoke to the otherof said members, a second pair of journals extending radially outwardly from diametrically opposite sides of each yoke and having a common axis perpendicular to the common axis of the first pair of journals, a torque transmitting element positioned between the yokes, bearings supported at opposite ends of the torque transmitting element for rocking movement relative,

to the latter and respectively connected to the second pair of journals on the first yoke, and ad ditional bearings supported at opposite ends of the torque transmitting element for rocking movement and respectively connected to the second pair of journals on the second yoke.

2. In a torque transmitting universal joint, driving and driven members having the adjacent ends spaced from each other, a pair or yokes positioned between the adjacent ends of the members, a pair of journals extending radially outwardly from diametrically opposite sides of each yoke and having a common axis, a pair of bearings respectively connecting the journals on one yoke to the adjacent end of one of said members, a second pair of bearings respectively connecting the journals on the secondyoke to the other of said members, a second pair of journals extending radially outwardly from diametrically opposite sides of each yoke and having a common axis perpendicular to the common axis of the first pair of journals, a torque transmitting element positioned between the yokes, a pair of bearings on opposite sides of the torque transmitting element at one end of the latter and connected together by a shaft rockably mounted in said end of the element, a second pair of bearings on opposite sides of the torque transmitting element at the opposite end of the latter and connected together by a shaft rockably mounted in said opposite end of the element, the bearings at opposite ends of the element on one side of the latter being respectively connected to the second pair of journals on the first yoke and the bearings at opposite ends of the element on the other side of the latter being respectively connected to the second pair of journals on said second yoke.

3.; In a torque transmitting universal joint, a pair of yokes spaced from each other, a pair of journals extending radially outwardly from diametricallyopposite sides of each yoke, a pair of bearings respectively engagingone journal of each pair and' connected; together by a shaft, a second pair of bearings respectively engaging the other journal of each pair and, connected together by. aishaft, and an intermediate torquedtransmitting element having the opposite ends connectedto said shafts between the bearings and supporting the shafts for rocking movement.

4. Inna torque transmitting universaljoint, a pair of'yokes. spaced from each. other, a pair of journals extending radially outwardly from diametrically opposite sides of each yoke, a pair of bearings respectively engaging one journal of eachpair and connected together by a shaft, a second pair of bearings respectively: engagingthe other journal of each pair and connected together by a shaft, a torque transmitting element between the yokes having the opposite ends slotted torespectively receive the portions of the shafts between the bearings andsupport the shafts for rocking movement, and means for retaining the shaftsinassembled relation with the slots in opposite' ends of the torque transmitting element.- I

5: In a torque transmitting universal 'J'o'int, driving and. driven members having the adjacent ends-spaced from each other, a pair of yokespositioned between the adjacent endstof the members, a pair of journals extending radially Out-1' wardly from diametrically opposite sides of each yoke and havinga' common-axis, a pair of bearings supported on one or the members for rocking movement relative to the latterand respectively-engaging the journal-s on one yoke, a sec and pair of bearings supported on the other men-t for rocking movement relative to the latter and respectively connected to the second: pair of journals onthe' first yoke, and additional bearings supported at opposite ends of the torque transmitting element for ranking movemeiit relative to the latter and respe'ctivei'y connectedto the second pair of journals on the sec- Ofid'yOke'f ANTON/F: GREINER. 

